Effects of the androgenic growth promoter 17‐β‐trenbolone on fecundity and reproductive endocrinology of the fathead minnow

Ankley, Gerald T.; Jensen, Kathleen; Makynen, Elizabeth A.; Kahl, Michael D.; Korte, Joseph J.; Hornung, Michael W.; Henry, Tala R.; Denny, Jeffrey S.; Leino, Richard L.; Wilson, Vickie S.; Cardon, Mary C.; Hartig, Phillip C.; Gray, L. Earl

doi:10.1002/etc.5620220623

Cited by 349 publications

(367 citation statements)

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“…17b-trenbolone is a strong androgen receptor agonist that depresses VTG production. Exposure to 17b-trenbolone at concentrations similar to those found in the environment decreases egg production in female FHMs and produces changes in plasma concentrations of 17b-estradiol, testosterone, and VTG (Ankley et al 2003). Increasing 17b-trenbolone exposure concentrations results in "U-shaped" responses for plasma 17b-estradiol, testosterone, and VTG concentrations (Ankley et al 2003).…”

Section: Introductionmentioning

confidence: 92%

“…The experimental designs and corresponding data summaries were described by Watanabe et al (2007). Among the 13 studies, one was a baseline reproduction study in unexposed (baseline) FHMs , and the rest were reproduction studies in which FHMs were exposed to 12 EDCs, including methoxychlor and methyltestosterone , fadrozole (Ankley et al 2002), 17b-trenbolone (Ankley et al 2003), flutamide (Jensen et al 2004), prochloraz and fenarimol (Ankley et al 2005a), perfluorooctane sulfonate (Ankley et al 2005b), 17a-trenbolone , prometon , ketoconazole , and haloperidol (Villeneuve et al 2010). For modeling purposes, we used fecundity data from the baseline reproduction study (data I), the control FHMs from the 12 EDC exposure experiments (data II), and FHMs exposed to 17b-trenbolone (data III) (Ankley et al 2003).…”

Section: Experimental Datamentioning

confidence: 99%

“…The PSD studies were performed in unexposed FHMs ) and FHMs exposed to prochloraz and fenarimol (Ankley et al 2005a), perfluorooctane sulfonate (Ankley et al 2005b), 17a-trenbolone , prometon , and haloperidol (Villeneuve et al 2010). The GSD studies were performed in FHMs exposed to methoxychlor and methyltestosterone , fadrozole (Ankley et al 2002), 17b-trenbolone (Ankley et al 2003), flutamide (Jensen et al 2004), and ketoconazole ).…”

Section: Experimental Datamentioning

confidence: 99%

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A computational model for asynchronous oocyte growth dynamics in a batch-spawning fish

Villeneuve

Jensen

et al. 2011

Can. J. Fish. Aquat. Sci.

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A computational model of oocyte growth dynamics (i.e., oocyte recruitment, growth, and spawning) in a batchspawning fish, fathead minnow (FHM, Pimephales promelas), has been developed. The model provides a quantitative link between oocyte growth dynamics and biochemical processes in FHMs through the absorption of vitellogenin (a lipoprotein precursor of egg yolk proteins) into oocytes, which contributes significantly to oocyte growth in fish. The model simulates the number and volume of oocytes in different batches within a FHM ovary. Model-predicted clutch sizes and spawning intervals matched the experimental data well for both unexposed FHMs and FHMs exposed to 17b-trenbolone (a relatively stable metabolite of trenbolone acetate, a synthetic androgen used as a growth promoter in livestock). Overall, the model presents a novel approach to simulating oocyte growth dynamics in a batch-spawning fish and meets an urgent need in ecotoxicological studies to link the effects of endocrine disrupting chemicals at a biochemical level to adverse effects upon reproduction.Résumé : Nous mettons au point un modèle informatique de la dynamique de la croissance des oocytes (c'est-à-dire, du recrutement des oocytes, de leur croissance et de leur ponte) chez un poisson qui pond par masses, la tête-de-boule (FHM, Pimephales promelas). Le modèle fournit un lien quantitatif entre la dynamique de la croissance des oocytes et les processus biochimiques chez la FHM par l'absorption dans les oocytes de la vitellogénine (un précurseur lipoprotéinique des protéines du vitellus), qui contribue significativement à la croissance des oocytes chez les poissons. Le modèle simule le nombre et le volume des oocytes dans les différentes masses dans un ovaire de FHM. Les tailles des pontes et les intervalles entre les pontes prédits par le modèle correspondent bien aux données expérimentales, tant chez les FHM non exposés que chez les FHM exposés au 17b-trenbolone (un métabolite relativement stable de l'acétate de trenbolone, un androgène de synthèse utilisé pour promouvoir la croissance chez le bétail). Globalement, le modèle représente une approche nouvelle pour simuler la dynamique de la croissance des oocytes chez un poisson qui pond ses oeufs par masses et répond à un besoin pressant dans les études écotoxicologiques de pouvoir relier au niveau biochimique les effets des produits chimiques disruptifs du système endocrinien aux conséquences négatives sur la reproduction.[Traduit par la Rédaction]

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Section: Introductionmentioning

confidence: 92%

Section: Experimental Datamentioning

confidence: 99%

Section: Experimental Datamentioning

confidence: 99%

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A computational model for asynchronous oocyte growth dynamics in a batch-spawning fish

Villeneuve

Jensen

et al. 2011

Can. J. Fish. Aquat. Sci.

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“…R. Soc. B 369: 20140022 [24,27,30,31] anti-androgens androgen receptor antagonism -impaired ovulation and spawning -impaired sexual differentiation -decreased nest defence -reproductive impairment -reduced probability of young of year survival** [32 -37] hormonal contraceptive oestrogen receptor activation -impaired ovulation and spawning -impaired sexual development -reproductive impairment [27] hormonal contraceptive oestrogen receptor antagonism* -impaired vitellogenesis, ovulation and spawning -impaired sexual differentiation -reproductive impairment** [38 -42] hormonal contraceptive progesterone receptor activation -reduced fecundity -reduced sperm motility -reproductive impairment [43 -46] anti-inflammatory glucocorticoid receptor activation -reduced oestradiol synthesis and fecundity -morphological abnormalities -decreased immune response -reproductive impairment -reduced probability of young of year survival** [47 -49] anti-depressants serotonin reuptake inhibition -morphological abnormalities -reduced fecundity -decreased food intake -impaired predator avoidance -reproductive impairment -reduced probability of young of year survival** [50 -55] anti-convulsant gamma-aminobutyric-acid receptor opening** sodium-channel inhibition -impaired predator avoidance -reduced probability of young of year survival** [56,57] non-steroidal anti-inflammatory drugs cyclooxygenase inhibition -impaired growth -impaired hatching -decreased spawning behaviour a -reduced fecundity a -increased probability of mortality** -reduced probability of young of year survival** -impaired reproduction a [58 -60] fibrates peroxisome proliferator-activated receptor activation -reduced fecundity -impaired reproduction [61] beta-blockers beta-adrenergic receptor antagonist -reduced growth -reduced probability of young of year survival** -increased probability of mortality** [62 -64] Aromatase inhibition is an established molecular initiating event for propiconazole, however other conazoles have been shown to inhibit other cytochrome P450 enzymes [76].…”

Section: (B) Conservation Of Molecular Target For Cross-species Extramentioning

confidence: 99%

Leveraging existing data for prioritization of the ecological risks of human and veterinary pharmaceuticals to aquatic organisms

LaLone

Berninger

Villeneuve

et al. 2014

Phil. Trans. R. Soc. B

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Medicinal innovation has led to the discovery and use of thousands of human and veterinary drugs. With this comes the potential for unintended effects on non-target organisms exposed to pharmaceuticals inevitably entering the environment. The impracticality of generating whole-organism chronic toxicity data representative of all species in the environment has necessitated prioritization of drugs for focused empirical testing as well as field monitoring. Current prioritization strategies typically emphasize likelihood for exposure (i.e. predicted/measured environmental concentrations), while incorporating only rather limited consideration of potential effects of the drug to non-target organisms. However, substantial mammalian pharmacokinetic and mechanism/mode of action (MOA) data are produced during drug development to understand drug target specificity and efficacy for intended consumers. An integrated prioritization strategy for assessing risks of human and veterinary drugs would leverage available pharmacokinetic and toxicokinetic data for evaluation of the potential for adverse effects to non-target organisms. In this reiview, we demonstrate the utility of read-across approaches to leverage mammalian absorption, distribution, metabolism and elimination data; analyse cross-species molecular target conservation and translate therapeutic MOA to an adverse outcome pathway(s) relevant to aquatic organisms as a means to inform prioritization of drugs for focused toxicity testing and environmental monitoring.

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“…More recently, studies have also reported traces of natural estrogens and androgenic steroid hormones at concentrations of a few nanograms per liter (ng/L) in river water and estuaries downstream from wastewater treatment facilities (Snow et al 2013). Mounting evidence indicates that steroid hormones can affect wildlife by causing non-lethal but adverse ecological health effects even though at low levels in the environment (Ankley et al 2003;Jensen et al 2006;Jobling et al 1998;Kidd et al 2007). Therefore, it is critical to analyze the occurrence and to study the fate and transport of these steroid hormones in environment.…”

Section: Introductionmentioning

confidence: 97%

Rapid screening of testosterone in the aquatic environment using direct analysis in real-time (DART) mass spectrometry

et al. 2016

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Testosterone (TES) in the aquatic environment was analyzed for the first time using direct analysis in realtime mass spectrometry (DART MS) without any sample pre-treatment. TES with the addition of 2H and its dehydration products was observed. The instrument parameters were studied systematically and optimized concerning the specific analyte. Limits of detection for the pure compound were 2.5 ng for TES spiked in raw wastewater samples and 500 pg in TES standards. The whole analysis time was within 1 min. A simple derivatization of TES by hydroxylamine and introducing ammonia as dopant gas for the sensitivity and intensity enhancement were also investigated. Both methods improved the intensity of the TES signal by about twofold. The results of this study illustrate that DART MS is capable to detect TES in complicated matrixes and could realize the rapid and direct screening of TES in the aquatic environment at a low nanogram range for pure compound without coupling with any pre-treatment tools.

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Effects of the androgenic growth promoter 17‐β‐trenbolone on fecundity and reproductive endocrinology of the fathead minnow

Cited by 349 publications

References 43 publications

A computational model for asynchronous oocyte growth dynamics in a batch-spawning fish

A computational model for asynchronous oocyte growth dynamics in a batch-spawning fish

Leveraging existing data for prioritization of the ecological risks of human and veterinary pharmaceuticals to aquatic organisms

Rapid screening of testosterone in the aquatic environment using direct analysis in real-time (DART) mass spectrometry

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